A multifunctional modular anti-seismic support assembly
Through modular design and a multi-level buffer system, the problems of long construction cycle and low installation efficiency of traditional seismic bracing are solved, achieving rapid assembly and multi-dimensional seismic resistance, adapting to complex pipeline layouts, and supporting reuse.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGZHOU MAICHEN BUILDING MATERIALS CO LTD
- Filing Date
- 2025-04-22
- Publication Date
- 2026-06-16
AI Technical Summary
Traditional seismic bracing has a long construction cycle, low installation efficiency, difficulty in adapting to complex pipeline layouts, and cannot effectively absorb multidimensional seismic energy. Furthermore, it is difficult to achieve rapid disassembly and reuse.
It adopts a modular design, including an anti-vibration base, anti-vibration components and connecting seats. It uses a combination of right-angled trapezoidal sliders, isosceles trapezoidal sliders and buffer springs to form a multi-level buffer system. Combined with a graphene layer to reduce friction, it achieves multi-dimensional anti-vibration and rapid assembly.
It achieves multi-level buffering, enables rapid assembly, is suitable for various loads, improves installation efficiency and seismic resistance, adapts to complex pipeline layouts, and supports reuse.
Smart Images

Figure CN224363474U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of seismic-resistant building equipment, specifically to a multifunctional modular seismic-resistant support assembly. Background Technology
[0002] With the acceleration of urbanization in my country, the seismic safety of building structures is receiving increasing attention. Traditional seismic bracing systems generally suffer from numerous technical bottlenecks. For example, existing seismic bracing systems mostly use welding or bolt fixing methods, requiring on-site cutting and drilling, resulting in long construction cycles and high environmental requirements. For instance, traditional C-shaped steel supports require on-site assembly, leading to low installation efficiency and difficulty in adapting to complex pipeline layouts. Some supports rely solely on single springs or rubber buffers, failing to effectively absorb multidimensional seismic energy, and existing supports are mostly customized designs, making rapid disassembly and reuse difficult. To address these issues, this utility model proposes a multifunctional modular seismic bracing component to overcome the shortcomings and deficiencies of existing technologies. Utility Model Content
[0003] The purpose of this utility model is to overcome the shortcomings of the existing technology and provide a multifunctional modular seismic bracing assembly.
[0004] The technical solution adopted in this utility model is as follows:
[0005] A multifunctional modular seismic bracing assembly includes a seismic base, a seismic component, and a connecting seat. The connecting seat is connected to the seismic base via the seismic component. The seismic base has an internal cavity and an opening at its top.
[0006] The anti-vibration component includes a pair of right-angled trapezoidal sliders, an isosceles trapezoidal slider, a first buffer spring assembly, and a load-bearing column. The two right-angled trapezoidal sliders are slidably disposed in the cavity. The bottom of the right-angled trapezoidal sliders is fixedly connected to the side wall of the cavity through the first buffer spring assembly. The hypotenuse of the isosceles trapezoidal slider abuts against the hypotenuse of the right-angled trapezoidal slider. The bottom of the isosceles trapezoidal slider is fixedly connected to the load-bearing column, which movably passes through the movable opening.
[0007] Preferably, the bottom of the cavity is further provided with a second buffer spring assembly, the top of the second buffer spring assembly is fixed to the top of the isosceles trapezoidal slider, and the top of the right-angled trapezoidal slider is provided with a slot for the second buffer spring assembly to move.
[0008] Preferably, both inclined surfaces of the isosceles trapezoidal slider are provided with abutment grooves, and the inclined surface of the right-angled trapezoidal slider is provided with abutment protrusions that abut against the abutment grooves.
[0009] Preferably, the abutment groove and the abutment protrusion are provided with a graphene layer.
[0010] Preferably, the top of the anti-seismic base and the bottom of the connecting seat are connected by a third buffer spring assembly.
[0011] Preferably, a reinforcing sleeve is provided between the movable openings.
[0012] The beneficial effects of this utility model are: by setting shock-absorbing components, this utility model achieves multi-level buffering and multi-dimensional shock resistance, which can withstand slow and fast impacts, and has good buffering and shock resistance effect. It can be quickly assembled and is suitable for various loads such as pipelines and equipment, and has significant practicality. Attached Figure Description
[0013] Figure 1 : A three-dimensional structural schematic diagram of this utility model.
[0014] Figure 2 Partial sectional view of this utility model.
[0015] Figure 3 : Cross-sectional view of the earthquake-resistant base of this utility model.
[0016] Figure 4 : A schematic diagram of the structure of the anti-seismic component of this utility model.
[0017] Figure 5 This utility model Figure 4 The exploded diagram. Detailed Implementation
[0018] The accompanying drawings are for illustrative purposes only and should not be construed as limiting the scope of this patent. To better illustrate this embodiment, some components in the drawings may be omitted, enlarged, or reduced, and do not represent the actual dimensions of the product. It is understandable to those skilled in the art that some well-known structures and their descriptions may be omitted in the drawings.
[0019] like Figure 1-5 As shown, a multifunctional modular seismic bracing assembly includes a seismic base 001, a seismic component 002, and a connecting seat 003. The connecting seat 003 is connected to the seismic base 001 through the seismic component 002. The seismic base 001 has a cavity 110 inside and an opening 120 on the top of the seismic base 001.
[0020] The seismic-resistant component 002 includes a pair of right-angled trapezoidal sliders 210, an isosceles trapezoidal slider 220, a first buffer spring assembly 230, and a load-bearing column 240. The two right-angled trapezoidal sliders 210 are slidably disposed in the cavity 110. The bottom of the right-angled trapezoidal sliders 210 is fixedly connected to the side wall of the cavity 110 through the first buffer spring assembly 230. The hypotenuse of the isosceles trapezoidal slider 220 abuts against the hypotenuse of the right-angled trapezoidal slider 210. The bottom of the isosceles trapezoidal slider 220 is fixedly connected to the load-bearing column 240, which movably passes through the movable opening 120.
[0021] Further optimizations to this solution include: Figure 1-5 As shown, the bottom of the cavity 110 is also provided with a second buffer spring assembly 004. The top of the second buffer spring assembly 004 is fixed to the top of the isosceles trapezoidal slider 220. The top of the right trapezoidal slider 210 is provided with a slot 211 for the second buffer spring assembly 004 to move. After the isosceles trapezoidal slider 220 is pressed down under the load, the second buffer spring assembly 004 absorbs energy for buffering.
[0022] Further optimizations to this solution include: Figure 1-5 As shown, the isosceles trapezoidal slider 220 has abutment grooves 221 on both inclined surfaces, and the right trapezoidal slider 210 has abutment protrusions 212 on the inclined surface that abut against the abutment grooves 221.
[0023] Further optimizations to this solution include: Figure 1-5 As shown, the abutment groove 221 and the abutment protrusion 212 are provided with a graphene layer 222, and the surface is coated with a 1-3μm graphene layer. Through its two-dimensional crystal structure, a self-lubricating film is formed, which reduces the sliding friction coefficient by 97% and reduces component wear.
[0024] Further optimizations to this solution include: Figure 1-5 As shown, the top of the anti-vibration base 001 and the bottom of the connecting seat 003 are connected by a third buffer spring group 005 to further absorb residual vibration energy and avoid secondary impact.
[0025] Further optimizations to this solution include: Figure 1-5 As shown, the active port 120 is equipped with a reinforcing sleeve 006.
[0026] The positional relationships described in the figures are for illustrative purposes only and should not be construed as limiting this patent. Clearly, the above embodiments of this utility model are merely examples to clearly illustrate the present utility model, and are not intended to limit the implementation of the present utility model. Those skilled in the art can make other variations or modifications based on the above description. It is neither necessary nor possible to exhaustively list all possible implementations here. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of this utility model should be included within the scope of protection of the claims of this utility model.
Claims
1. A multifunctional modular seismic bracing assembly, characterized in that: It includes an anti-seismic base (001), an anti-seismic component (002), and a connecting seat (003). The connecting seat (003) is connected to the anti-seismic base (001) through the anti-seismic component (002). The anti-seismic base (001) has a cavity (110) inside and an opening (120) at the top. The anti-vibration component (002) includes a pair of right-angled trapezoidal sliders (210), an isosceles trapezoidal slider (220), a first buffer spring assembly (230), and a load-bearing column (240). The two right-angled trapezoidal sliders (210) are slidably disposed in the cavity (110). The bottom of the right-angled trapezoidal slider (210) is fixedly connected to the side wall of the cavity (110) through the first buffer spring assembly (230). The hypotenuse of the isosceles trapezoidal slider (220) abuts against the hypotenuse of the right-angled trapezoidal slider (210). The bottom of the isosceles trapezoidal slider (220) is fixedly connected to the load-bearing column (240). The load-bearing column (240) movably passes through the movable opening (120).
2. The multifunctional modular seismic bracing assembly according to claim 1, characterized in that: The bottom of the cavity (110) is also provided with a second buffer spring assembly (004), the top of the second buffer spring assembly (004) is fixed to the top of the isosceles trapezoidal slider (220), and the top of the right trapezoidal slider (210) is provided with a slot (211) for the second buffer spring assembly (004) to move.
3. The multifunctional modular seismic bracing assembly according to claim 1, characterized in that: The isosceles trapezoidal slider (220) has abutment grooves (221) on both inclined surfaces, and the right-angled trapezoidal slider (210) has abutment protrusions (212) on the inclined surface that abut against the abutment grooves (221).
4. The multifunctional modular seismic bracing assembly according to claim 3, characterized in that: The abutment groove (221) and the abutment protrusion (212) are provided with a graphene layer (222).
5. The multifunctional modular seismic bracing assembly according to claim 1, characterized in that: The top of the anti-seismic base (001) and the bottom of the connecting seat (003) are connected by a third buffer spring assembly (005).
6. The multifunctional modular seismic bracing assembly according to claim 1, characterized in that: A reinforcing sleeve (006) is provided between the movable ports (120).